Title :
Numerical Modeling of Multi-Core Fiber Laser
Author :
Elkin, N.N. ; Napartovich, A.P. ; Troshchieva, V.N. ; Vysotsky, D.V.
Author_Institution :
Troitsk Inst. for Innovation & Fusion Res., Moscow
fDate :
June 29 2006-July 1 2006
Abstract :
The problem of phase locking is of importance in the development of multi-core fiber lasers. It is known that only strong-coupled system has a chance to be phase locked despite non-identity of channels. In case of the strong inter-channel coupling the traditional theoretical approach based on expansion over modes of individual cores fails. We have developed 3D diffraction numerical code, and results of its implementation to simulations of 7-core hexagonal fiber structure experimentally studied recently are reported. Detailed analysis of light propagation in this system, where self-organization effect was observed, shows that the dominant mechanism of coherence formation in an array of co-propagating beams is mode spatial filtering produced by the gain assembly. Non-linear resonance refraction exerts a weak influence on appearance of self-organization
Keywords :
fibre lasers; laser mode locking; laser modes; light coherence; light diffraction; light propagation; light refraction; nonlinear optics; 3D diffraction numerical code; 7-core fiber structure; coherence formation; copropagating beams; gain assembly; hexagonal fiber structure; interchannel coupling; light propagation; mode spatial filtering; multicore fiber laser; nonlinear resonance refraction; phase locking; self-organization; self-organization effect; strong-coupled system; Coherence; Diffraction; Fiber lasers; Filtering; Laser mode locking; Laser modes; Laser theory; Numerical models; Optical arrays; Optical propagation;
Conference_Titel :
Laser and Fiber-Optical Networks Modeling, 8-th International Conference on
Conference_Location :
Kharkiv
Print_ISBN :
1-4244-0233-6
Electronic_ISBN :
1-4244-0234-4
DOI :
10.1109/LFNM.2006.251994
